Eubacterial tmRNA sequences and uses thereof

ABSTRACT

The present invention is directed to eubacterial tmDNA sequences and the corresponding tmRNA sequences. The present invention is further directed to alignments of eubacterial tmDNA sequences and the use of the sequences and sequence alignments for the development of antibacterial drugs. The present invention is also directed to the use of the sequences for the development of diagnostic assays.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a national stage filing under 35 U.S.C. §371 of PCT/US00/08988 filed on 6 Apr. 2000. The present application is also related to and claims priority under 35 U.S.C. §119(e) to U.S. provisional patent application Ser. No. 60/128,058 filed on 7 Apr. 1999.

BACKGROUND OF THE INVENTION

The present invention is directed to eubacterial tmDNA sequences and the corresponding tmRNA sequences. The present invention is further directed to alignments of eubacterial tmDNA sequences and use of the sequences and sequence alignments for the development of antibacterial drugs. The present invention is also directed to the use of the sequences for the development of diagnostic assays.

The publications and other materials used herein to illuminate the background of the invention or provide additional details respecting the practice are incorporated by reference, and for convenience are respectively grouped in the appended List of References.

Eubacterial tmRNAs (10Sa RNAs) are unique since they function, at least in E. coli, both as tRNA and as mRNA (for a review, see Muto et al., 1998). These ˜360±10% nucleotide RNAs are charged with alanine at their 3′-ends (Komine et al., 1994; Ushida et al., 1994) and also have a short reading frame coding for 9 to 27 amino acids depending on the bacterial species. E. coli tmRNA mediates recycling of ribosomes stalled at the end of terminatorless mRNAs; via a trans-translation process (Tu et al., 1995; Keiler et al., 1996; Himeno et al., 1997). In E. coli, this amino acid tag is co-translationally added to polypeptides synthesized from mRNAs lacking a termination codon, and the added 11 amino acid C-terminal tag makes the protein a target for specific proteolysis (Keiler et al., 1996).

Structural analyses based on phylogenetic (Felden, et al., 1996; Williams and Bartel, 1996) and probing (Felden et al., 1997; Hickerson et al., 1998) data have led to a compact secondary structure model encompassing 6 helices and 4 pseudoknots. tmRNAs have some structural similarities with canonical tRNAs, especially with tRNA acceptor branches. E. coli tmRNA contains two modified nucleosides, 5-methyluridine and pseudouridine, located in the tRNA-like domain of the molecule, in a seven-nucleotide loop mimicking the conserved sequence of T loops in canonical tRNAs (Felden et al., 1998).

Fifty-three tmRNA sequences are now known from both experimental data and Blast searches on sequenced genomes (summarized in Williams, 1999; Wower and Zwieb, 1999). These sequences cover only 10 phyla, less than one third of the known bacterial taxa. It is desired to determine additional tmRNA sequences and to use the tmRNA sequences for drug development.

SUMMARY OF THE INVENTION

The present invention relates to eubacterial tmDNA sequences and the corresponding tmRNA sequences. The present invention further relates to alignments of eubacterial tmDNA sequences and use of the sequences and sequence alignments for the development of antibacterial drugs.

In one aspect of the present invention, an extensive phylogenetic analysis was performed. Fifty-eight new tmDNA sequences including members from nine additional phyla were determined. Remarkably, tmDNA sequences could be amplified from all species tested apart from those in the alpha-Proteobacteria. This aspect of the invention allowed a more systematical study of the structure and overall distribution of tmRNA within eubacteria.

In a second aspect of the invention, alignments are made with the newly isolated tmDNA sequences and previously disclosed tmRNA sequences.

In a third aspect of the invention, the alignments of the tmRNA sequences allow the identification of targets for development of antibacterial drugs.

In a fourth aspect of the invention, the novel tmDNA or tmRNA sequences of the present invention are used to develop diagnostic assays, such as amplification-based assays, for the bacterial species disclosed herein.

BRIEF DESCRIPTION OF THE FIGURES

FIGS. 1A–1B show the effect of the annealing temperature (FIG. 1A) and magnesium concentration (FIG. 1B) on amplifying eubacterial tmRNA genes from genomic DNAs using PCR. A: Varying the annealing temperature from 50° to 70° C. during the PCR amplification of Thermus aquaticus (1). B; Varying the magnesium concentration to amplify tmDNA genes from Thermus aquaticus (1), negative effect of increasing the magnesium concentration), Acholeplasma laidlawii (2), positive effect of increasing the magnesium concentration, the upper band is the tmDNA gene) and from Mycoplasma salivarium (3), no discernible effect of magnesium ions in that concentration range). The arrows point toward the 4 novel tmDNA genes that have been sequenced.

FIG. 2 shows the distribution of tmDNA sequences within eubacterial genomes. The circled phyla or subgroups contain tmDNA sequences and those shaded are new members of this category. The numbers shown close to each phylum are the 51 tmDNA sequences that have are disclosed herein and the numbers in parenthesis are the 53 tmDNA sequences that were previously known (summarized in Williams, 1999; Wower and Zwieb, 1999). The environmental samples are indicated with a dashed line as their connection to the tree is unknown. The 5 alpha-Proteobacteria in which tmDNA sequences were not detected by PCR analysis are labeled “PCR” and the 3 analyzed by Blast search of the complete, or nearly complete, sequenced genomes are labeled “database”.

FIGS. 3A, 3B and 3C show the sequence alignment, structural domains and structural features for the tmRNA of several species of Firmicutes. The tmRNA sequences are set forth in SEQ ID NOs:67–87.

FIGS. 4A and 4B show the sequence alignment, structural domains and structural features for the tmRNA of several species of Thermophiles. The tmRNA sequences are set forth in SEQ ID NOs:88–99.

FIGS. 5A and 5B show the sequence alignment, structural domains and structural features for the tmRNA of several species of Cyanobacteries (5A) and chloroplasts (5B). The tmRNA sequences of the Cyanobacteries are set forth in SEQ ID NOs:100–103, and the tmRNA sequences of the chloroplasts are set forth in SEQ ID NOs:104–108.

FIGS. 6A and 6B show the sequence alignment, structural domains and structural features for the tmRNA of several species of Mycoplasmes. The tmRNA sequences are set forth in SEQ ID NOs:109–117.

FIGS. 7A-1, 7A-2, 7B, 7C and 7D show the sequence alignment, structural domains and structural features for the tmRNA of several species of Mesophiles (7A-1, 7A-2, 7C, 7D) and environmental sludge (7B). The tmRNA sequences of the Mesophiles are set forth in SEQ ID NOs:118–123 and 125–128, and the tmRNA sequence of the environmental sludge is set forth in SEQ ID NO:124.

FIGS. 8A and 8B show the sequence alignment, structural domains and structural features for the tmRNA of several species of Actinobacteries (8A) and Spirochaetes (8B). The tmRNA sequences of the Actinobacteries are set forth in SEQ ID NOs:132–136, and the tmRNA sequences of the Spirochaetes are set forth in SEQ ID NOs:137–142.

FIGS. 9A and 9B show the sequence alignment, structural domains and structural features for the tmRNA of several species of Pourpres beta. The tmRNA sequences are set forth in SEQ ID NOs:143–154.

FIGS. 10A, 10B and 10C show the sequence alignment, structural domains and structural features for the tmRNA of several species of Pourpres gamma. The tmRNA sequences are set forth in SEQ ID NOs:155–169.

FIGS. 11A and 11B show the sequence alignment, structural domains and structural features for the tmRNA of several species of Pourpres delta (11A) and Pourpres epsilon (11B). The tmRNA sequences of the Pourpres delta are set forth in SEQ ID NOs:170–172, and the tmRNA sequences of the Pourpres epsilon are set forth in SEQ ID NOs:173–175.

DETAILED DESCRIPTION OF THE INVENTION

The present invention is directed to eubacterial tmDNA sequences and the corresponding tmRNA sequences. The present invention is further directed to alignments of eubacterial tmDNA sequences and use of the sequences and sequence alignments for the development of antibacterial drugs.

The novel eubacterial tmDNA sequences determined in accordance with the present invention are set forth in Tables 1–58, below. The alignment of tmRNA sequences is shown in FIGS. 3A–11B, which also show the structural domains and structural features of the tmRNA. The present invention also includes the tmRNA sequences set forth in these figures to the extent they differ from the sequences set forth in Tables 1–58.

The sequences, especially as identified by the sequence alignment, represent targets for the development of drugs which may be broadly applicable to many kinds of bacteria, or may be broadly applicable only to a particular genera of phylum of bacteria, or may be specifically applicable to a single species of bacteria. Thus, the present invention is further directed to the development of drugs for the therapeutic treatment of bacteria, generically or specifically. Suitable drugs are developed on the basis of the tmRNA sequences as described herein.

For all the novel tmRNA sequences, as well as with the ones that are already known, there are systematically several structural domains that are always found. These domains can be used as targets for the development of drugs which may be genera specific or which may be eubacteria specific. These domains are either RNA helices which can be sometimes interrupted by bulges or pseudoknots. The RNA helices which are always present are H1, H2, H5 and H6. Helices H1 and H6 are found in all canonical transfer RNAs. Thus, H1 and H6 are not good targets for drug development because drugs that would target them will also interfere with the biology of the individual that has a given disease. Consequently, very good candidates for development of drugs for targeting as many bacteria as possible are helices H2 and H5. Moreover, helices H2 and H5 are critical for the folding of all these tmRNA since both of them connect the two ends of the molecule together. Disruption of either H2 or H5 with a specific drug would lead to inactive tmRNA molecules in vivo. Similarly, pseudoknots PK1, PK2 and PK3 are always found in the bacterial tmRNAs. Since these pseudoknots are not found in all canonical transfer RNAs, they can also be targeted with specific drugs. Disruption of either PK1 or PK2 or PK3 with a specific drug would lead to inactive tmRNA molecules in vivo.

In addition to developing drugs which broadly target many bacteria, drugs are developed which are more genera specific. For trying to target specifically a given bacteria or a complete phylum, the coding sequence (shown in all the alignments) is a very good candidate. Indeed, this region of the RNA is very accessible for DNA antisense binding (such as shown for Escherichia coli; Matveeva et al., 1997), and thus, is also available for interaction with other drugs. Moreover, the coding sequence is a critical functional domain of the molecule in its quality-control mechanism in cells.

Interestingly, some structural domains are present only in a given bacterial phyla and could be targeted for discovering a drug that will be specific of a phylum, but not of the others. For example:

-   -   (1) in the cyanobacteria, the fourth pseudoknot PK4 is made of         two smaller pseudoknots called PK4a and PK4b;     -   (2) in the mycoplasma, helix H2 is made of only 4 base-pairs         instead of 5 in the other species;     -   (3) for two sequences of chlorobium as well as Bacteroides         thetaiotaomicron and ppm gingiv., there is an additional domain         just downstream of the coding sequence that is unique to them;     -   (4) there is always a stem-loop in the coding sequence of the         actinobacteria (Felden et al., 1999); and     -   (5) all the beta proteobacteria possess a sequence insertion in         pseudoknot PK2 (shown in the alignment).

The novel sequences described herein, when aligned, show that specific structural domains within tmRNA are strictly conserved, as for example pseudoknot PK1 is located upstream (at the 5′-side) of the coding sequence. As previously disclosed, this pseudoknot is a target for future anti-bacterial drugs. Moreover, recent data have shown that this PK1 pseudoknot, among all the four pseudoknots within tmRNA gene sequences (sometimes there's only 2 or 3 detectable pseudoknots, depending upon the sequences), is the only one that its correct folding is essential for the biological activity of tmRNA (Nameki et al., 1999; Nameki et al., 2000).

It has recently been discovered that even the alpha-proteobacteria possess tmRNA genes. These genes are permuted and are made in two parts, connected via a processed linker. These tmRNA gene sequences from alpha-proteobacteria were not found in the course of the present invention because usual PCR methods could not amplify them.

Recent reports have shown that whereas the gene encoding tmRNA is non-essential in E. coli (does not kill the bacteria when disrupted), it is indeed essential in Neisseria gonorrheae (Huang et al., 2000). Also, tmRNA is directly involved in Salmonella typhymurium pathogenticity (Julio et al., 2000).

In summary, tmRNA genes are present in all eubacterial genomes, with no exceptions, but are not present in any genomes from archebacteries or eukaryotes, with the exception of some chloroplasts. The very specific location of tmRNA genes within one of the three main kingdoms of life make them ideal targets for the design of novel antibiotics that will, in principle, interfere very weakly with human biochemistry, compared to usual antibiotics. For a recent review about designing novel antibiotics, see Breithaupt (1999).

The present invention is also directed to diagnostic assays and kits for the detection of bacterial infection, particularly infections caused by bacterial agents disclosed herein. In one embodiment, the coding sequence of each bacterial species is used to design specific primers for use in amplification-based diagnostic assays for infectious diseases. Specific primers are designed in accordance with well known techniques, and such design is readily done by a skilled artisan. Amplification-based diagnostic assays are performed in accordance with conventional techniques well known to skilled artisans. Examples of amplification-based assays include, but are not limited to, polymerase chain reaction (PCR) amplification, strand displacement amplification (SDA), ligase chain reaction (LCR) amplification, nucleic acid sequence based amplification (3SR or NASBA) and amplification methods based on the use of Q-beta replicase.

Drugs which target the sequences described herein are active agents can be formulated in pharmaceutical compositions, which are prepared according to conventional pharmaceutical compounding techniques (Remington's, 1990). The composition may contain the active agent or pharmaceutically acceptable salts of the active agent. These compositions may comprise, in addition to one of the active substances, a pharmaceutically acceptable excipient, carrier, buffer, stabilizer or other materials well known in the art. Such materials should be non-toxic and should not interfere with the efficacy of the active ingredient. The carrier may take a wide variety of forms depending on the form of preparation desired for administration, e.g., intravenous, oral, intrathecal, epineural or parenteral.

For oral administration, the compounds can be formulated into solid or liquid preparations such as capsules, pills, tablets, lozenges, melts, powders, suspensions or emulsions. In preparing the compositions in oral dosage form, any of the usual pharmaceutical media may be employed, such as, for example, water, glycols, oils, alcohols, flavoring agents, preservatives, coloring agents, suspending agents, and the like in the case of oral liquid preparations (such as, for example, suspensions, elixirs and solutions); or carriers such as starches, sugars, diluents, granulating agents, lubricants, binders, disintegrating agents and the like in the case of oral solid preparations (such as, for example, powders, capsules and tablets). Because of their ease in administration, tablets and capsules represent the most advantageous oral dosage unit form, in which case solid pharmaceutical carriers are obviously employed. If desired, tablets may be sugar-coated or enteric-coated by standard techniques. The active agent can be encapsulated to make it stable to passage through the gastrointestinal tract while at the same time allowing for passage across the blood brain barrier. See for example, WO 96/11698.

For parenteral administration, the compound may dissolved in a pharmaceutical carrier and administered as either a solution of a suspension. Illustrative of suitable carriers are water, saline, dextrose solutions, fructose solutions, ethanol, or oils of animal, vegetative or synthetic origin. The carrier may also contain other ingredients, for example, preservatives, suspending agents, solubilizing agents, buffers and the like. When the compounds are being administered intrathecally, they may also be dissolved in cerebrospinal fluid.

The active agent is preferably administered in an therapeutically effective amount. The actual amount administered, and the rate and time-course of administration, will depend on the nature and severity of the condition being treated. Prescription of treatment, e.g. decisions on dosage, timing, etc., is within the responsibility of general practitioners or specialists, and typically takes account of the disorder to be treated, the condition of the individual patient, the site of delivery, the method of administration and other factors known to practitioners. Examples of techniques and protocols can be found in Remington's Pharmaceutical Sciences (18).

Alternatively, targeting therapies may be used to deliver the active agent more specifically to certain types of cell, by the use of targeting systems such as antibodies or cell-specific ligands. Targeting may be desirable for a variety of reasons, e.g. if the agent is unacceptably toxic, or would otherwise require too high a dosage, or otherwise be unable to enter the target cells.

Antisense active agents can also be delivered by techniques described in U.S. Pat. Nos. 5,811,088; 5,861,290 and 5,767,102.

EXAMPLES

The present invention is further detailed in the following Examples, which are offered by way of illustration and are not intended to limit the invention in any manner. Standard techniques well known in the art or the techniques specifically described below are utilized.

Example 1 Materials and Methods

1. Extaction of Genomic DNA

Bacterial genomic DNAs were prepared from ˜10 mg freeze-dried cells provided from ATCC (American Type Culture Collection, Virginia, USA). Cell pellets were resuspended in 750 μL of lysis buffer (50 mM Tris (pH 8.0), 50 mM EDTA and 20% sucrose). 150 μL of a 10 mg/mL solution of lysozyme was mixed and let stand at room temperature for 15 min. 150 μL of 1% SDS was added and let stand at room temperature for 15 minutes. Four to five phenol/chloroform extractions were performed, until the sample was clear and there was no interphase. Two to five μL of a 10 mg/mL solution of RNase DNase-free was added and incubated at room temperature for 30 minutes. After a phenol/chloroform extraction of the enzyme, the genomic DNA was precipitated with 1/10 volume of 3M NaOAc (pH 5.5) and 1 volume isopropanol, and stored at −20° C. for 2 hours. After centrifugation, the genomic DNAs were washed with 70% ethanol, vacuum-dried and diluted in sterile water to a final concentration of 10 ng/μL.

2. Primer Sets for PCR Reactions

The following primer sets were used during the PCR:

-   -   primer set A (based on E. coli tmRNA termini):         -   5′-GGG GCT GAT TCT GGA TTC GAC-3′ (SEQ ID NO:1) and         -   5′-TGG AGC TGG CGG GAG TTG AAC-3′ (SEQ ID NO:2);     -   primer set B (based on T. neapolitana tmRNA termini):         -   5′-GGG GGC GGA AAG GAT TCG ACG-3′ (SEQ ID NO:3) and         -   5′-TGG AGG CGG CGG GAA TCG AAC-3′ (SEQ ID NO:4);     -   primer set C (based on M. pneumoniae tmRNA termini):         -   5′-GGG GAT GTC ATG GTT TTG ACA-3′ (SEQ ID NO:5) and         -   5′-TGG AGA TGG CGG GAA TCG AAC-3′ (SEQ ID NO:6); and     -   primer set D (based on C. tepidum tmRNA termini):         -   5′-GGG GAT GAC AGG CTA TCG ACA-3′ (SEQ ID NO:7) and         -   5′-TGG AGA TGG CGG GAC TTG AAC-3′ (SEQ ID NO:8).

3. PCR Reaction

Sequences of tmRNA genes were obtained by polymerase chain reaction (PCR) in 25 μL using 40 ng of genomic DNA per reaction. The following general scheme was utilized for all of the sequences:

-   -   (a) 94° C. to 96° C. for 4 min. (first denaturation of genomic         DNAs, done only once); then     -   (b) 35 to 40 PCR cycles with 2.5 to 5 Units of Taq DNA         polymerase in a 25 μL reaction volume, according to the         following scheme (40 ng of genomic DNAs/PCR reaction):         -   1. denature at 94° to −96° C. for 25 to 30 sec;         -   2. anneal at 44° to 55° C. for 20 to 30 sec; and         -   3. extension at 72° C. for 10 sec.             The magnesium conc. was optimized for each phyla from 3.5 to             13.5 mM.

4. Elution of Amplified DNAs

The various PCR-amplified tmDNA bands were gel purified (5% PAGE), stained (ethidium bromide staining), cut using a sterile razor blade, and shaken over-night (passive elution, using a vibrator) in a 350 μl solution containing 10 mM Tris-HCl buffer (pH 8.1). The following day, the PCR amplified tmDNAs were ethanol precipitated, washed in 70% ETOH, vacuum dried and the DNA pellets were dissoved in 18 μl of RNase-DNase free sterile water.

5. DNA Sequencing

Six μL of amplified DNAs were added to 3.2 picomoles of the primer that was used in the PCR. To verify the novel tmDNA sequences, each of the two primers were used independently to sequence each of the two PCR-amplified DNA strands. Some tmDNAs were already engineered at their 5′-ends with a T7 promoter, to be able to transcribe directly the tmDNAs into tmRNAs by in vitro transcription.

Dye terminator sequencing was achieved at the DNA sequencing facility of the Human Genetics Institute. In addition to novel tmRNA sequences that are not available publicly, several tmDNA sequences that were already known have been verified and several sequencing mistakes have been found and corrected (especially for Alcaligenes eutrophus tmRNA).

Example 2 Amplification Reactions for Eubacterial tmDNA

Eubacterial tmDNA was amplified by PCR in accordance with Example 1, using the following conditions.

Acidobacterium:

Primer Set B; Annealing temp. during PCR: 53° C. for 20 sec; Mg²⁺ conc.: 4.5 mM.

Coprothermobacter:

Primer Set B; Annealing temp. during PCR: 55° C. for 30 sec; Mg²⁺ conc.: 5.5 mM.

Cytophagales:

Primer Set A; Annealing temp. during PCR: 46° C. for 30 sec; Mg²⁺ conc.: 4.5 mM.

Dictyoglomus:

Primer set B; Annealing temp. during PCR: 55° C. for 30 sec; Mg²⁺ conc.: 4.5 mM.

Environmental Samples:

Sludge DNA

Primer set C; Annealing temp. during PCR: 51° C. for 20 ^(sec; Mg) ²⁺ conc.: 13.5 mM.

Rumenal Fluid DNA

Primer set D; Annealing temp. during PCR: 50° C. for 30 sec; Mg²⁺ conc.: 9.5 mM.

Fibrobacter:

Primer set A; Annealing temp. during PCR: 51° C.; Mg²⁺ conc.: 3.5 mM.

Firmicutes:

Fusobacteria:

Primer set A; Annealing temp. during PCR: 52° C.; Mg²⁺ conc.: 5.5 mM.

High G-C:

Primer set A; Annealing temp. during PCR: 50–55° C.; Mg²⁺ conc.: 4.5 mM.

Low G-C:

Primer sets A or B; Annealing temp. during PCR: 52° C.; Mg²⁺ conc.: 5.5 to 7.5 mM.

Mycoplasmes:

Primer set A; Annealing temp. during PCR: 52° C.; Mg²⁺ conc.: 3.5 to 5.5 mM.

Green Non-Sulfur:

Primer sets A or B; Annealing temp. during PCR: 46 to 52° C.; Mg²⁺ conc.: 4.5 mM.

Green Sulfur:

Primer set A; Annealing temp. during PCR: 46° C.; Mg²⁺ conc.: 4.5 mM.

Planctomycetales:

Primer set A; Annealing temp. during PCR: 48 to 52° C.; Mg²⁺ conc.: 7.5 mM.

Proteobacteria:

Beta:

Primer sets A and/or B; Annealing temp. during PCR: 50° C. for 25 sec; Mg²⁺ conc.: 3.5 mM.

Delta:

Primer set B; Annealing temp. during PCR: 55° C.; Mg²⁺ conc.: 3.5 to 4.5 mM.

Epsilon:

Primer set A; Annealing temp. during PCR: 46° C. for 30 sec; Mg²⁺ conc.: 3.5 mM.

Gamma:

Primer set A; Annealing temp. during PCR: 44 C for 30 sec; Mg²⁺ conc.: 5.5 mM.

Spirochetes:

Primer set A; Annealing temp. during PCR: 52° C.; Mg²⁺ conc.: 4.5 mM.

Thermodesulfobacterium:

Primer set B; Annealing temp. during PCR: 55° C.; Mg²⁺ conc.: 5.5 mM.

Thermotogales:

Primer set B; Annealing temp. during PCR: 46° C.; Mg²⁺ conc.: 7.5 mM.

Deinococcales:

Primer set B; Annealing temp. during PCR: 52° C.; Mg²⁺ conc.: 3.5 mM.

Verrucomicrobia:

Primer set A; Annealing temp. during PCR: 53° C. for 25 sec; Mg²⁺ conc.: 3.5 mM.

Example 3 Amplification of Eubacterial tmDNA

Specific PCR amplification of tmRNA genes was achieved for both thermophilic and mesophilic eubacterial tmRNA genes. For the novel tmDNA genes found in thermophiles, both the magnesium concentration and the annealing temperature (FIG. 1A) were optimized. As shown in FIG. 1A, a specific amplification of Thermus aquaticus tmDNA was observed with an annealing temperature around 50° C., whereas at higher temperatures there is a gradual decrease in the amount of amplified tmDNA. For mesophiles, the magnesium concentration during PCR was critical (FIG. 1B), but the annealing temperature could vary from 44° C. to 60° C. without significant effects on the amplification. FIG. 1B shows various effects of increasing the magnesium concentration on the PCR amplification of three novel eubacterial tmDNA genes. Increasing magnesium concentration from 3.5 mM to 5.5 mM has either a negative (FIG. 1B, panel 1), a positive (FIG. 1B, panel 2) or no effect on specifically amplifying eubacterial tmDNA genes.

According to these procedures, tmRNA genes from many eubacteria including known human pathogens were amplified. The PCR was facilitated by sequence conservation at both 5′ and 3′ ends and was performed as described (Williams and Bartel, 1996), with modifications. This study was initiated to collect further sequences from eubacterial tmDNA genes, as well as to test experimentally whether tmDNA genes could be found in all bacterial phyla or subgroups. 51 new tmDNA sequences were determined (FIG. 2), including sequences from members of 8 additional phyla and 1 subgroup (shaded boxes in FIG. 2). The 58 new tmDNA sequences are set forth in Tables 1–58. This brings coverage to a total of 104 sequences in 19 bacterial phyla. Interestingly, tmDNA sequences could be amplified from all species tested apart from those in the alpha-Proteobacteria. Five genomic DNAs from alpha-Proteobacteria (Agrobacterium tumefaciens, Bartonella henselae, Bartonella quintana, Rhodospirillum rubrum and Rickettsia prowazekii) were extensively checked using various oligonucleotides, annealing temperatures and magnesium concentrations. No specific amplified tmDNA sequences were detected in this subgroup. Moreover, no putative tmDNA sequences could be identified (results herein and Williams, 1999) by Blast searches on the 1 fully sequenced (Rickettsia prowazekii) and 2 nearly completed (Caulobacter crescentus and Rhodobacter capsulatus) alpha-proteobacterial genomes (FIG. 2).

It cannot be ruled out that tmDNA sequences may have largely diverged in the alpha-proteobacterial sub-group compared to other bacterial phyla, and that both PCR methods and Blast searches are missing the relevant sequences. While tmRNA is dispensable in E. coli (Ando et al., 1996), it is striking that it has been found in all bacteria tested other than the alpha-Proteobacteria. The alpha-Proteobacteria have undergone reductive evolution. This has been more intensive in one of the two sub-classes than in the other (Gray and Spencer, 1996), but tmRNA sequences have not been found even in the sub-class with the larger genome. Based on sequence comparison, the alpha-Proteobacteria and mitochondria are evolutionary relatives (Yang et al., 1985; Andersson et al., 1998). The drastic downsizing in what has become mitochondrial genomes means that it is not reasonable to draw inferences on the relationship between alpha-Proteobacteria and mitochondria based on their mutual apparent absence of tmRNA. It is nevertheless, of interest, that at least some chloroplasts and cyanelle genomes have tmDNA sequences, and the cyanobacteria, with which they are evolutionary related, also have tmRNA.

TABLE 1 tmDNA Sequence for Acidobacterium capsulatum (Acidobacterium) (SEQ ID NO:9) GGGGGCGGAAAGGATTCGACGGGGTTGACTGCGGCAAAGAGGCATGCCGGGGGGTGGGCACCCG TAATCGCTCGCAAAACAATACTTGCCAACAACAATCTGGCACTCGCAGCTTAATTAAATAAGTT GCCGTCCTCTGAGGCTTCGCCTGTGGGCCGAGGCAGGACGTCATACAGCAGGCTGGTTCCTTCG GCTGGGTCTGGGCCGCGGGGATGAGATCCACGGACTAGCATTCTGCGTATCTTGTCGCTTCTAA GCGCAGAGTGCGAAACCTAAAGGAATGCGACTGAGCATGGAGTCTCTTTTCTGACACCAATTTC GGACGCGGGTTCGATTCCCGCCGCCTCCACCA

TABLE 2 tmDNA Sequence for Coprothermobacter proteolyticus (60 degrees) (SEQ ID NO:10) GGGGGCGGAAAGGATTCGACGGGGAGTCGGAGCCTTGAGCTGCAGGCAGGGTTGGCTGCCACAC CTTAAAAAGGGTAGCAAGGCAAAAATAAATGCCGAACCAGAATTTGCACTAGCTGCTTAATGTA AGCAGCCGCTCTCCAAACTGAGGCTGCATAAGTTTGGAAGAGCGTCAACCCATGCAGCGGCTCT TAAGCAGTGGCACCAGCTGTTTAAGGGTGAAAAGAGTGGTGCTGGGCAGTGCGGTTGGGCTTCC TGGGCTGCACTGTCGAGACTTCACAGGAGGGCTAAGCCTGTAGACGCGAAAGGTGGCGGCTCGT CGGACGCGGGTTCGATTCCCGCCGCCTCCACCA

TABLE 3 tmDNA Sequence for Bacteroides thetaiotaomicron (bacteroides/flavobacterium) (SEQ ID NO:11) GGGGCTGATTCTGGATTCGACAGCGGGCAGAAATGGTAGGTAAGCATGCAGTGGGTCGGTAATT TCCACTTAAATCTCAGTTATCAAAACTTTATCTGGCGAAACTAATTACGCTCTTGCTGCTTAAT CGAATCACAGTAGATTAGCTTAATCCAGGCACTAGGTGCCAGGACGAGACATCACTCGGAAGCT GTTGCTCCGAAGCATTCCGGTTCAGTGGTGCAGTAACATCGGGGATAGTCAGAAGCGGCCTCGC GTTTTTGATGAAACTTTAGAGGATAAGGCAGGAATTGATGGCTTTGGTTCTGCTCCTGCACGAA AATTTAGGCAAAGATAAGCATGTAGAAAGCTTATGATTTCCTCGTTTGGACGAGGGTTCAACTC CCGCCAGCTCCACCA

TABLE 4 tmDNA Sequence for Dictyoglomus thermophilum (70 degrees) (SEQ ID NO:12) GGGGCTGATTCTGGATTCGACAGGGAGTACAAGGATCAAAAGCTGCAAGCCGAGGTGCCGTTAC CTCGTAAAACAACGGCAAAAAAGAAGTGCCAACACAAATTTAGCATTAGCTGCTTAATTTAGCA GCTACGCTCTTCTAACCCGGGCTGGCAGGGTTAGAAGGGTGTCATAATGAGCCAGCTGCCCCTT CCGACTCCCCTAAGGAAGGGAAAGATGTAGGGGATAGGTGCTTACAGAATCCTGCGGGAGGGAG TCTGTAAGTGCCGAAAAGTTAAAACTCCCGCTAAGCTTGTAGAGGCTTTTGATTCTTGCTCTCT GGACGCGGGTTCAACTCCCGCCAGCTCCACCA

TABLE 5 tmDNA Sequence for Environmental Sample from Rumenal Fluid (SEQ ID NO:13) ACGCCCTTGTCTCAGACGAGGGCACTCGTTAAAAAGTCTGAAAAGAATAACTGCAGAACCTGTA GCTATGGCTGCTTAATTTAAGGGCAACCCTTGGATCCGCCTCCATCCCGAAGGGGTGGCATCCG AGTCGCAAATCGGGATAGGATGGATCTTGGCAACGAGGAGTACATCCGAAATTTGTCGCTGCTG GCTGAAGCATCGCCGTTCCTCTTTGGGCGTGGCAAGGCAAGATTAAATTCAGAGGATAAGCGTG TAGTAGCGAGTGAGTAGGTGTTTTTGGACGCGGGTTCAAGTCCCGCCATCTCCACCA

TABLE 6 tmDNA Sequence for Environmental Sample from Sludge (SEQ ID NO:14) GGGGATGTCATGGTTTTGACAGGGAACCAGGAGGTGTGAGATGCATGCCGGAGACGCTGTCCGC TCCGTTATCAAGCAGCAAACAAAACTAATTGCAAACAACAATTACTCCTTAGCAGCGTAAGCAG CTAACGTTCAACCTCTCCGGACCGCCGGGAGGGGATTTGGGCGTCGAAACAGCGCGGACGCTCC GGATAGGACGCCCATAATATCCGGCTAAGACCATGGGTCTGGCTCTCGCGGGTCTGATTGTCTT CCACCGCGCGGGCCGCGATCAAAGACAACTAAGCATGTAGGTTCTTGCATGGCCTGTTCTTTGG ACGCGGGTTCGATTCCCGCCATCTCCACCA

TABLE 7 tmDNA Sequence for Fibrobacter succinogenes (Fibrobacter) (SEQ ID NO:15) GGGGCTGATTCTGGATTCGACAGGGTTACCGAAGTGTTAGTTGCAAGTCGAGGTCTCAGACGAG GGCTACTCGTTAAAAAGTCTGAAAAAAAATAAGTGCTGACGAAAACTACGCACTCGCTGCCTAA TTAACGGCAACGCCGGGCCTCATTCCGCTCCCATCGGGGTGTACGTCCGGACGCAATATGGGAT AGGGAAGTGTCATGCCTGGGGGCATCTCCCGAGATTTTCTAGGCTGGTCAAACTCCGCGCCGAC CTTCTTGGGCGTGGATAAGACGAGATCTTAAATTCGAAGGGAACACTTGTAGGAACGTACATGG ACGTGATTTTGGACAGGGGTTCAACTCCCGCCAGCTCCA

TABLE 8 tmDNA Sequence for Fusobacterium mortiferum (SEQ ID NO:16) GGGGCTGATTCTGGATTCGACGGGGTTATGAGGTTATAGGTAGCATGCCAGGATGACCGCTGTG AGAGGTCAACACATCGTTTAGATGGAAACAGAAATTACGCTTTAGCTGCTTAATTAGTCAGCTC ACCTCTGGTTTCTCTCTTCTGTAGGAGAATCCAACCGAGGTGTTACCAATATACAGATTACCTT TAGTGATTTCTCTAAGCTCAAAGGGACATTTTAGAGAATAGCTTCAGTTAGCCCTGTCTGCGGG AGTGATTGTTGCGAAATAAAATAGTAGACTAAGCATTGTAGAAGCCTATGGCGCTGGTAGTTTC GGACACGGGTTCAACTCCCGCCAGCTCCAA

TABLE 9 tmDNA Sequence for Corynebacterium xerosis (gram +, high G-C content) (SEQ ID NO:17) GGGGCTGATTCTGGATTCGACTTCGTACATTGAGCCAGGGGAAGCGTGCCGGTGAAGGCTGGAG ACCACCGCAAGCGTCGCAGCAACCAATTAAGCGCCGAGAACTCTCAGCGCGACTACGCCCTCGC TGCCTAAGCAGCGACCGCGTGTCTGTCAGACCGGGTAGGCCTCTGATCCGGACCCTGGCATCGT TTAGTGGGGCTCGCTCGCCGACTTGGTCGCAAGGGTCGGCGGGGACACTCACTTGCGACTGGGC CCGTCATCCGGTCATGTTCGACTGAACCGGAGGGCCGAGCAGAGACCACGCGCGAACTGCGCAC GGAGAAGCCCTGGCGAGGTGACGGAGGACCCGGGTTCAACTCCCGCCAGCTCCACCA

TABLE 10 tmDNA Sequence for Micrococcus luteus (parfait) (SEQ ID NO:18) GGGGCTATTCTGGATTCGACGGTGTGTGTCGCGTCGGGAGAAGCGGGCCGAGGATGCAGAGTCA TCTCGTCAAACGCTCTCTGCAAACCAATAAGTGCCGAATCCAAGCGCACTGACTTCGCTCTCGC TGCCTGATCAGTGATCGAGTCCGTCACCCCGAGGTCGCTGTCGCCTCGGATCGTGGCGTCAGCT AGATAGCCACTGGGCGTCACCCTCGCCGGGGGTCGTGACGCCGACATCAATCCGGCTGGGTCCG GGTTGGCCGCCCGTCTGCGGGACGGCCAGGACCGAGCAACACCCACAGCAGACTGCGCCCGGAG AAGACCTGGCAACACCTCATCGGACGCGGGTTCAACTCCCGCANTCCCACCA

TABLE 11 tmDNA Sequence for Mycobacterium smegmatis (SEQ ID NO:19) TCATCTCGGCTTGTTCGCGTGACCGGGAGATCCGAGTAGAGACATAGCGAACTGCGCACGGAGA GGGGCTGATTCCTGGATTCGACTTCGAGCATCGAATCCAGGGAAGCGTGCCGGTGCAGGCAAGA GACCACCGTAAGCGTCGTTGCAACCAATTAAGCGCCGATTCCAATCAGCGCGACTACGCCCTCG CTGCCTAAGCGACGGCTGGTCTGTCAGACCGGGAGTGCCCTCGGCCCGGATCCTGGCATCAGCT AGAGGGACCCACCCACGGGTTCGGTCGCGGGACCTGTGGGGACATCAAACAGCGACTGGGATCG AGCCTCGAGGACATGCCGTAGGACCCGGGTTCAACTCCCGCCAGCTCCACCA

TABLE 12 tmDNA Sequence for Bacillus badius (SEQ ID NO:20) GGGGGTGATTCTGGATTCGACAGGGATAGTTCGAGCTTGGGCTGCGAGCCGGAGGGCCGTCTTC GTACCAACGCAAACGCCTAAATATAACTGGCAAAAAAGATTTAGCTTTAGCTGCCTAATATAGG TTCAGCTGCTCCTCCCGCTATCGTCCATGTAGTCGGGTAAGGGGTCCAAACTTAGTGGACTACG CCGGAGTTCTCCGCCTGGGGACAAAGGAAGAGATCAATCAGGCTAGCTGCCCGGACGCCCGTCG ATAGGCAAAAGGAACAGTGAACCCCAAATATATCGACTACGCTCGTAGACGTTCAAGTGGCGTT ATCTTTGGACGTGGGTTCAACTCCCGCCAGCTCCA

TABLE 13 tmDNA Sequence for Bacillus brevis (SEQ ID NO:21) GGGGGCGGAAAGGATTCGACGGGGATGGTAGAGCATGAGAAGCGAGCCGGGGGGTTGCGGACCT CGTCACCAACGCAAACGCCATTAACTGGCAACAAACAACTTTCTCTCGCTGCTTAATAACCAGT GAGGCTCTCCCACTGCATCGGCCCGTGTGCCGTGGATAGGGCTCAACTTTAACGGGCTACGCCG GAGGCTTCCGCCTGGAGCCAAAGGAAGAAGACCAATCAGGCTAGGTGCCAGGTCAGCGCGTCAC TCCGCGAATCTGTCACCGAAACTCTAAACGAGTGACTGCGCTCGGAGATGCTCATGTATCGCTG TTTTCGGACGGGGGTTCGATTCCCGCCGCCTCACCCA

TABLE 14 tmDNA Sequence for Bacillus thermoleovorans (50–60 degres) (SEQ ID NO:22) GGGGGCGGAAAGGATTCGACGGGGGTAGGTCGAGCTTAAGCGGCGAGCCGAGGGGGACGTCCTC GTAAAAACGTCACCTAAAGATAACTGGCAAACAAAACTACGCTTTAGCTGCCTAATTGCTGCAG CTAGCTCCTCCCGCCATCGCCCGCGTGGCGTTCGAGGGGCTCATATGGAGCGGGCTACGCCCAA ATCCGCCGCCTGAGGATGAGGGAAGAGACGAATCAGGCTAGCCGCCGGGAGGCCTGTCGGTAGG CGGAACGGACGGCGAAGCGAAATATACCGACTACGCTCGTAGATGCTTAAGTGGCGATGCCTCT GGACGTGGGTTCGATTCCCGCCGCCTCCCCACCA

TABLE 15 tmDNA Sequence for Clostridium innocuum (SEQ ID NO:23) GGGGGCGGAAAGGATTCGACGGGGATATGTCTGGTACAGACTGCAGTCGAGTGGTTACGTAATA ACCAATTAAATTTAAACGGAAAAACTAAATTAGCTAACCTCTTTGGTGGAAACCAGAGAATGGC TTTCGCTGCTTAATAACCGATATAGGTTCGCAGCCGCCTCTGCATGCTTCTTCCTTGACCATGT GGATGTGCGCGTAAGACGCAAGGGATAAGGAATCTGGTTTGCCTGAGATCAGATTCACGAAAAT TCTTCAGGCACATTCATCAGCGGATGTTCATGACCTGCTGATGTCTTAATCTTCATGGACTAAA CTGTAGAGGTCTGTACGTGGGGCTGTTTCTGGACAGGAGTTCGATTCCCGCCGCCTCACCACCA

TABLE 16 tmDNA Sequence for Clostridium lentocellum (SEQ ID NO: 24) GGGGGCGGAAAGGATTCGACGGGGGTCACATCTACTGGGGCAGCCATCCGTAGAACGCCGGAGT CTACGTTAAAAGCTGGCACTTAAAGTAAACGCTGAAGATAATTTAGCAATCGCTGCCTAATTAA GGCGCAGTCCTCCTAGGTCTTCCGCAGCCTAGATCAGGGCTTCGACTCGCGGATCCTTCACCTG GCAAAGCTTTGAGCCAACGTGAACACTATGAAGCTACTAAAATCTAGAGCCTGTCTTTGGGCGC TAGATGGAGGGAATGTCAAAACAAAGAATATGATGGTAGAGACCACGCTATATGGGCTTTCGGA CAGGGGTTCGATTCCCGCCGCCTTCACCA

TABLE 17 tmDNA Sequence for Clostridium perfringens (SEQ ID NO: 25) GGGGCTGATTCTGGATTCGACGGGGGTAAGATGGGTTTGATAAGCGAGTCGAGGGAAGCATGGT GCCTCGATAATAAAGTATGCATTAAAGATAAACGCAGAAGATAATTTTGCATTAGCAGCTTAAT TTAGCGCTGCTCATCCTTCCTCAATTGCCCACGGTTGAGAGTAAGGGTGTCATTTAAAAGTGGG GAACCGAGCCTAGCAAAGCTTTGAGCTAGGAACGGAATTTATGAAGCTTACCAAAGAGGAAGTT TGTCTGTGGACGTTCTCTGAGGGAATTTTAAAACACAAGACTACACTCGTAGAAAGTCTTACTG GTCTGCTTTCGGACACGGGTTCAACTCCCGCCACTCCA

TABLE 18 tmDNA Sequence for Clostridium stercorarium (SEQ ID NO: 26) GGGGGCGGAAAGGATTCGACGGGGTTATTGAAGCAAGAGTAGCGGGTAGAGGATTCTCGTTGGC CTCTTTAAAAAACGAGAGCTAAAAATAAACGCAAACAACGATAACTACGCTTTAGCTGCTGCGT AAGTAACACGCAGCCCGTCGGCCCCGGGGTTCCTGCGCCTCGGGATACCGGCGTCATCAAGGCA GGGAACCAGCCGGATCAGGCTTCAGGTCCGGTGGGATTTAATGAAGCTACCGACTTATAAAGCC TGTCTCTGGGCGTTATAAGAAGGGAATGTCAAAACAGAGACTGCACCCGGAGAAGCTCTTGTGG ATATGGTTCCGGACACGAGTTCGATTCCCGCCGCCTCCACCA

TABLE 19 tmDNA Sequence for Enterococcus faecium (sp.) (SEQ ID NO: 27) GGGGCTGATTATGGATTCGACAGGATNGTTGAGCTTGAATTGCGTTTCGTAGGTTACGGCTACG TTAAAACGTTACAGTTAAATATAACTGCTAAAAACGAAAACAATTCTTTCGCTTTAGCTGCCTA AAAACCAGCTAGCGAAGATCCTCCCGGCATCGCCCATGTGCTCGGGTCAGGGTCCTAATCGAAG TGGGATACGCTAAATTTTTCCGTCTGTAAAATTTAGAGGAGCTTACCAGACTAGCAATACAAGA ATGCCTGTCACTCGGCACGCTGTAAAGCGAACCTTTAAATGAGTGTCTATGAACGTAGAGATTT AAGTGGGAATATGTTTTGGACGCGGGTTCAACTCCCGCCAGCTCCACCA

TABLE 20 tmDNA Sequence for Heliobacillus mobilis (photosyn/gram +) (SEQ ID NO: 28) GGGGCTGATTCTGGATTCGACGGGGAACGTGTTTGCTTGGGATGCGAGCCGGGTTGCCGCCAGG ACCGTAAAAAGGGCGGAAGGCTTTAATTGCCGAAGATAACTACGCTTTAGCTGCTTAATTGCAG TCTAACCTCTTCTCCTCTGTGCTCTCGGTGAGGATGTAAGGGGTCATTTAAGAGAGCTGGCTTC GACCAATTCTCGGAGGTCCAAGCGAGATTTATCGAGATAGCCTGACCAACGCTCTGTCTGCCGT GCGGAAGGAAGGCGAAATCTAAAACGACAGACTACGCTCGTAGTGTCCTTTGTGGGCATTTCTT CGGACGCGGGTTCAACTCCCGCCAGCTCCACCA

TABLE 21 tmDNA Sequence for Heliospirillum gestii (SEQ ID NO: 29) GGGGCTGATTCTGGATTCGACGGGGAACGTGTTTGCTTAGGACGCGAGCCGGGTTGCCGCCAGG ACCGTAAAAAGGGCGGAAGGCTTTAATTGCCGAAGATAACTACGCTTTAGCTGCTTAATTGCAG TCTAACCTCTTCTCCTCTGTGCTCTCGGTGAGGATGTAAGGGGTCATTTAAGAGAGCTGGCTCG AACCAATTCTCGGAGGTTCGGGTAAGACTTATCGAGATAGCCTGACCAACGCTCTGTCTGCCGT GCGGAAGGATGGCGAAATCTAAAACGACAGAATACGCTCGTAGTGTCCTTTGTGGGCATTTCTT CGGACGCGGGTTCAACTCCCGCCAGCTCCACCA

TABLE 22 tmDNA Sequence for Lactobacillus acidophilus (SEQ ID NO: 30) GGGGCTGATTCTGGATTCGACAGGCGTAGACCCGCATTGACTGCGGTTCGTAGGTTACGTCTAC GTAAAAACGTTACAGTTAAATATAACTGCAAATAACAAAAATTCTTACGCATTAGCTGCTTAAT TTAGCGCATGCGTTGCTCTTTGTCGGTTTACTCGTGGCTGACACTGAGTATCAACTTAGCGAGT TACGTTTAACTACCTCACCTGAATAGTTGAAAAGAGTCTTAGCAGGTTAGCTAGTCCATACTAG CCCTGTTATATGGCGTTTTGGACTAGTGAAGTTCAAGTAATATAACTATGATCGTAGAGGTCAG TGACGAGATGCGTTTGGACAGCGGGTTCAACTCCCGCCAGCTCCACCA

TABLE 23 tmDNA Sequence for Staphylococcus epidermidis (SEQ ID NO: 31) GGGGCTGATTCTGCATTCGACAGGGGTCCCCGAGCTTATTAAGCGTGTGGAGGGTTGGCTCCGT CATCAACACATTTCGGTTAAATATAACTGACAAATCAAACAATAATTTCGCAGTAGCTGCGTAA TAGCCACTGCATCGCCTAACAGCATCTCCTACGTGCTGTTAACGCGATTCAACCCTAGTAGGAT ATGCTAAACACTGCCGCTTGAAGTCTGTTTAGATGAAATATAATCAAGCTAGTATCATGTTGGT TGTTTATTGCTTAGCATGATGCGAAAATTATCAATAAACTACACACGTAGAAAGATTTGTATCA GGACCTCTGGACGCGGGTTCAACTCCCGCCAGCTCCACCA

TABLE 24 tmDNA Sequence for Streptococcus faecium (SEQ ID NO: 32) GGGGCTGATTCTGGATTCGACAGGCACAGTTTGAGCTTGAATTGCGTTTCGTAGGTTACGTCTA CGTTAAAACGTTACAGTTAAATATAACTGCTAAAAACGAAAACAACTCTTACGCTTTAGCTGCC TAAAAACAGTTAGCGTAGATCCTCTCGGCATCGCCCATGTGCTCGAGTAAGGGTCTCAAATTTA GTGGGATACGTGACAACTTTCCGTCTGTAAGTTGTTAAAGAGATCATCAGACTAGCGATACAGA ATGCCTGTCACTCGGCAAGCTGTAAAGCGAAACCACAAATGAGTTGACTATGAACGTAGATTTT TAAGTGGCGATGTGTTTGGACGCGGGTTCAACTCCCGCCGTTCCACCA

TABLE 25 tmDNA Sequence for Thermoanaerobacterium saccharolyticum (Bacillus/clostridium) (SEQ ID NO: 33) GGGGTAGTAGAGGTAAAAGTAGCGAGCCGAGGTTCCATCTGCTCGTAAAACGGTGGACTTAAAT ATAAACGCAAACGATAATTTAGCTTACGCTGCTTAATTACAAGCAGCCGTTCAACCTTTGATTC CCACATCAAAGGATTGGGCGTCGATTTAGTGGGGAACTGATTTATCAAAGCTTTGAGATAAATC GGATTTTATGAAGCTACCAAAGCAGTTATCCTGTCACTGGGAGAACTGCAGAGGGAATGTCAAA ACAGTGACTGCGCTCGGAGAAGCTTTTACTGTGACACCTTCGGACCGGGGTTCAACTCCCGCCA GCTCCACCA

TABLE 26 tmDNA Sequence for Mycoplasma fermentans (SEQ ID NO: 34) GGGGCTGATTCTGGATTCGACATGCATTGGGTGATACTAATATCAGTAGTTTGGCAGACTATAA TGCATCTAGGCTTTATAATCGCAGAAGATAAAAAAGCAGAAGAAGTTAATATTTCTTCACTTAT GATTGCACAAAAAATGCAATCACAATCAAACCTTGCTTTCGCTTAGTTAAAAGTGACAAGTGGT TTTAAAGTTGACATTTTCCTATATATTTTAAAATCGGCTTTTAAGGAGAACAGGAGTCTGAAAG GGTTCCAAAAATCTATATTGTTTGCATTTCGGTAGTATAGATTAATTAGAAATGATAAACTGTA AAAAGTATTGGTATTGACTTGGTGTGTGGACTCGGGTTCAACTCCCGCCAGCTCCACCA

TABLE 27 tmDNA Sequence for Mycoplasma hyorhinis (SEQ ID NO: 35) GGGGCTGATTCTGGATTCGACATACATAAAAGGATATAAATTGCAGTGGTCTTGTAAACCATAA GACAATTTCTTTACTAAGCGGAAAAGAAAACAAAAAAGAAGATTATTCATTATTAATGAATGCT TCAACTCAATCAAATCTAGCTTTTGCATTTTAAAAAACTAGTAGACCAATTTGCTTCTCACGAA TTGTAATCTTTATATTAGAGAATAGTTAAAAATCTGATCACTTTTTAATGAATTTATAGATCAC AGGCTTTTTTAATCTTTTTGTTATTTTAGATAAAGAGTCTTCTTAAAAATAACTAAACTGTAGG AATTTATATTTAATTATGCGTGGACCCGGGTTCAACTCCCGCCAGCTCCACCA

TABLE 28 tmDNA Sequence for Mycoplasma pirum (SEQ ID NO: 36) GGGGAGTCATGGTTTTGACATGAATGATGGACCCATAGAGGCAGTGGGGTATGCCCCTTATAGC TCAAGGTTTAAATTAACCGACAAAACTGACGAAAACGTTGCCGTTGATACAAATTTATTAATCA ACCAACAAGCTCAATTTAACTACGCATTTGCATAGTATAAAAAAATAAATTGTGCTACTCATTG TAATTAGGTTACTAAATTACTTTGTTTTATATAGTCCTGTAACTAGTTCTAGTGATGTCTATAA ACTAGAATGAGATTTATAGACTTATTTGTTGGCGGTTGTGCCATAGCCTAAATCAACAAAGACA ATTTATTTATGGTACTAAACTGTAGATTCTATGATGAAATTATTTGTGGAAACGGGTTCGATTC CCGCCATCTCCACCA

TABLE 29 tmDNA Sequence for Mycoplasma salivarium (SEQ ID NO: 37) GGGGCTGATTCTGGATTCGACAGGCATTCGATTCATTATGTTGCAGTGGTTTGCAAACCATAAG GCACTAGGCTTTTTTAAACGCAAAAGACCAAAAAACAGAAGATCAAGCAGTTGATCTAGCATTT ATGAATAATTCACAAATGCAATCAAATCTAGTTTTCGCTTAGTAAAATTAGTCAATTTATTATG GTGCTCAACATAATAAATGGTAGTATGAGCTTAATATCATATGATTTTAGTTAATATGATAGGA TTTGTAACTAAACTATGTTATAGAAATTTGTAAATTATATATATGACATAGGAAATTTAATTTA CTAAACTGTAGATGCATAATGTTGAAGATGTGTGGACCGGGGTTCAACTCCCGCCAGCTCCACCA

TABLE 30 tmDNA Sequence for Herpetosiphon aurantiacus (SEQ ID NO: 38) GGGGGCGGAAAGGATTCGACGGGGAGGGCCAATCGTAAGTGGCAAGCCGAGACGCTGAGCCTCG TTAAATCGGCAACGCCATTAACTGGCAAAAACACTTTCCGCGCTCCTGTAGCGCTTGCTGCCTA ATTAAGGCAACACGTCTCTACTAGCCTCAGCCCGATGGGCTTGTAGCGGCGACACTTAGTCGGG TCGCTCCCCTAGTTATGTCTGTGGGCTAGGGGCTAAGATTAACAGGCTGGTCGTGGCCCGCTTT GTCTATCGGGTGGTGCACCGATAAGATTTAATCAATAGACTACGCTTGTAGATGCTTGCGGTTT AACTTTTTGGACGCGGGTTCGATTCCCGCCGCCTCACCACCA

TABLE 31 tmDNA Sequence for Thermomicrobium roseum (352 nts, temp. 70 degrees, green non sulfur) GGGGCTGATTCTGGATTCGACAGGGCCGTAGGTGCGAGGATTGCAGGTCGAGGTCGCCCACGAA CTCGTAAAAAGGGGCAGCCAAGTAACTGGCGAGCGCGAACTCGCTCTGGCTGCGTAATTCACGC AGCCACGTCTGCCCGGACCCTTCCCTGGTGGGTTCGGAGCGGGCGCCGCAAGACCGGGGTGCCC CTGGCCCAAGCGCCGGTGCGGGCCAGGTCAAGCGTGATCCGGCTCGGCTGACCGGGATCCTGTC GGTGGGAGCCTGGCAGCGACAGTAGAACACCGACTAAGCCTGTAGCATATCCTCGGCTGAACGC TCTGGACGCGGGTTCAACTCCCGCCAGCTCCACCA (SEQ ID NO:39)

TABLE 32 tmDNA Sequence for Chlorobium limicola GGGGCTGATTCTGGATTCGACAGGATACGTGTGAGATGTCGTTGCACTCCGAGTTTCAGCATGG ACGGACTCGTTAAACAAGTCTATGTACCATTAGATGCAGACGATTATTCGTATGCAATGGCTGC CTGATTAGCACAAGTTAACTCAGACGCCATCGTCCTGCGGTGAATGCGCTTACTCTGAAGCCGC CGGATGGCATAACCCGCGCTTGAGCCTACGGGTTCGCGCAAGTAAGCTCCGTACATTCATGCCC GAGGGGCTGTGCGGGTAATTTCTCGGGATAAGGGGACGAACGCTGCTGGCGGTGTAATCGGCCC ACGAAAACCCAATCACCAGAGATGAGTGTGGTGACTGCATCGAGCAGTGTTTTGGACGCGGGTT CAACTCCCGCCAGCTCCACCA (SEQ ID NO:40)

TABLE 33 tmDNA Sequence for Pirellula staleyi (planctomyces) GGGGCTGATTCTGGATTCGACCGGATAGCCTGAAGCGAATACGGCGTGCCGTGGTTGATCAGAT GGCCACGTAAAAAGCTGATCACAAACTTAACTGCCGAGAGCAATCTCGCACTTGCTGCCTAACT AAACGGTAGCTTCCGACTGAGGGCTTTAGCCGGAGAGGCCCAAAAGTTGGTCACCAAATCCGGA CCGCCTCGTGCCATGATCGAAACGCACGAGGTCAAAAAAGTTTCGATCTAGTGCAGGGTGTAGC CAGCAGCTAGGCGACAAACTGTGCAAAAATCAAATTTTCTGCTACGCACGTAGATGTGTTCGTG AAAATGTCTCGGGACGGGGGTTCAACTCCCGCCACTCCACCA (SEQ ID NO:41)

TABLE 34 tmDNA Sequence for Planctomyces limnophilus GGGGCTGATTCTGGATTCGACAACCTCTCAAGAGGAGCGTGGCCACTATGGGACTCGATTATGT TGAATTCGTCATGGATCTTGAAGAGACCTTCGACATCAAACTGGATGACAAACATTTTTCAGCA GTCAAAACACCACGCGATTTGGCAATCATTATTCGGGATCAATTAGCTGCTGAAGGCAGAATCT GGGATGAATCGAATGCTTTTCGCAAAATCTCGAATTTGAATTGGACGATGTTGCCCGAGTTCCG GATGTGGACTCAAATCAAAAGCTCTCTACCAGTTTCTTTTCACCGACTGCGTCCCAGCACCCGT CTCGTTCAACTCCCGCCANTCCACCA (SEQ ID NO:42)

TABLE 35 tmDNA Sequence for Planctomyces maris GGGGCTGATTCTGGATTCGACTGGTTCACCGTATGTTAAGGTGGCGGTGCCGTGGTTGATCAGT TGGCCACGTAAAAAGCTGATCACAATCTAATTGCAAACAAGCAATTTTCAATGGCTGCTTAATA AAAGCAACCCCGGCTTAGGAATCTCTGTCTGAGGAGTCCGACAGCTGGTCACAAAATCAGACTG GTATCAGATCAATGTCCGCTCCGTCTGATACGAGATTCGTGGTGGACTGGTTTCCAACAGGCTC TGTTTATCGTGCCCGAAGAAACGAGACTCAAACGATAAAATATGCACCGTAGAGGCTTTAGCTG AGGGTTCACAGGACGCGGGTTCAACTCCCGCCAGCTCCACCA (SEQ ID NO:43)

TABLE 36 tmDNA Sequence for Alcaligenes eutrophus GGGGTTGATTCTGGATTCGACGTGGGTTACAAAGCAGTGGAGGGCATACCGAGGACCCGTCACC TCGTTAATCAATGGGAATGCAATAACTGCTAACGACGAACGTTACGCACTGGCCGCTTAATTGC GGCCGTCCTCGCACTGGCTCGCTGACGGGCTAGGGTCGCAAGACCACGCGAGGTCATTTACGTC AGATAAGCTCCGGAAGGGTCACGAAGCCGGGGACGAAAACCTAGTGACTCGCCGTCGTAGAGCG TGTTCGTCCGCGATGCGCCGGTTAAATCAAATGACAGAACTAAGTATGTAGAACTCTCTGTGGA GGGCTTACGGACGCGGGTTCAACTCCCGCCAGCTCCACCA (SEQ ID NO:44)

TABLE 37 tmDNA Sequence for Alcaligenes faecalis (beta proteobacteria) GGGGGCGGAAAGGATTCGACGGGGGTCAAGAAGCAGCACAGGGCGTGTCGAGCACCAGTACGCT CGTAAATCCACTGGAAAACTATAAACGCCAACGACGAGCGTTTCGCTCTAGCCGCTTAAGGCTG GGCCACTGCACTAATTTGTCTTTGGGTTAGGTAGGGCAACCTACAGCAGTGTTATTTACAAAGA ATCGAATCGGTCTGCGCCACGAAGTCCGGTTCTAAAACTTAGTGGATCGCCAAGGAAAGGCCTG TCAATTGGCATAGTCCAAGGTTAAAACTTAAAATTAATTGACTACACATGTAGAACTGTCTGTG GACGGCTTGCGGACGGGGGTTCGATTCCCGCCGCCTCCACCA (SEQ ID NO:45)

TABLE 38 tmDNA Sequence for Chromobacterium violaceum (beta-purple) GGGGCTGATTCTGGATTCGACGGGGGTTGCGAAGCAGATGAGGGCATACCGGGATTTCAGTCAC CCCGTAAAACGCTGAATTTATATAGTCGCAAACGACGAAACTTACGCTCTGGCAGCCTAACGGC CGGCCAGACACTACAACGGTTCGCAGATGGGCCGGGGGCGTCAAAACCCTGTAGTGTCACTCTA CATCTGCTAGTGCTGTTCCGGGTTACTTGGTTCAGTGCGAAATAATAGGTAACTCGCCAAAGTC CAGCCTGTCCGTCGGCGTGGCAGAGGTTAAATCCAAATGACACGACTAAGTATGTAGAACTCAC TGTAGAGGACTTTCGGACGCGGGTTCAACTCCCGCCAGCTCCACCA (SEQ ID NO:46)

TABLE 39 tmDNA Sequence for Hydrogenophaga palleroni (beta-purple) GGGGCTGATTCTGGATTCGACGTGGGTTCGGACGCGCAGCAGGGCATGTCGAGGTTCTGTCACC TCGTAAATCAGCAGAAAAAAACCAACTGCAAACGACGAACGTTTCGCACTCGCCGCTTAAACAC CGGTGAGCCTTGCAACAGCAGGCCGATGGGCTGGGCAAGGGGGTCGCAAGACCTCCCGGCTGCA AGGTAATTTACATCGGCTGGTTCTGCGTCGGGCACCTTGGCGCAGGATGAGATTCAAGGATGCT GGCTTCCCGTTTAGCGTGCCACTGCGCGACTCGGGCGGCGAGACCCAAATCAGACGGCTACACA TGTAGAACTGCTCGAAAAAGGCTTGCGGACGGGGGTTCAACTCCCGCCAGCTCCACCA (SEQ ID NO:47)

TABLE 40 tmDNA Sequence for Methylobacillus glycogenes (beta-purple) GGGGGCGGAAAGGATTCGACGGGGGTTGCAAAGCAGCGCAGGGCATACCGAGGCCTAGTCACCT CGTAAATAAACTAGAACAAGTATAGTCGCAAACGACGAAACTTACGCTCTAGCCGCTTAATCCC GGCTGGACGCTGCACCGAAGGGCCTCTCGGTCGGGTGGGGTAACCCACAGCAGCGTCATTAAGA GAGGATCGTGCGATATTGGGTTACTTAATATCGTATTAAATCCAAGGTAACTCGCCTGCTGTTT GCTTGCTCGTTGGTGAGCATCAGGTTAAATCAAACAACACAGCTAAGTATGTAGAACTGTCTGT GGAGGGCTTGCGGACGGGGGTTCGATTCCCGCCGCCTCACCACCA (SEQ ID NO:48)

TABLE 41 tmDNA Sequence for Nitrosomonas cryotolerans (beta-purple) GGGGCTGATTCTGGATTCGACGTGGGTTGCAAAGCAGCGCAGGGCATACCGAGGACCAGAATAC CTCGTAAATACATCTGGAAAAAAATAGTCGCAAACGACGAAAACTACGCTTTAGCCGCTTAATA CGGCTAGCCTCTGCACCGATGGGCCTTAACGTCGGGTCTGGCAACAGACAGCAGAGTCATTAGC AAGGATCGCGTTCTGTAGGGTCACTTTACAGAACGTTAAACAATAGGTGACTCGCCTGCCATCA GCCCGCCAGCTGGCGGTTGTCAGGTTAAATTAAAGAGCATGGCTAAGTATGTAGAACTGTCTGT AGAGGACTTGCGGACGCGGGTTCAACTCCCGCCAGTCCACCA (SEQ ID NO:49)

TABLE 42 tmDNA Sequence for Pseudomonas testosteroni GGGGCTGATTCTGGATTCGACGTGGGTTCGGGACCGGTGCGGTGCATGTCGAGCTTGAGTGACG CTCGTAAATCTCCATTCAAAAAACTAACTGCAAACGACGAACGTTTCGCACTCGCCGCTTAATC CGGTGAGCCTTGCAACAGCACGCTAGTGGGCTGGGCAAGGGGGTAGCAATACCTCCCGGCTGCA AGGGAATTTTCATTAGCTGGCTGGATACCGGGCTTCTTGGTATTTGGCGAGATTTTAGGAAGCT GGCTACCCAAGCAGCGTGTGCCTGCGGGGTTTGGGTGGCGAGATTTAAAACAGAGCACTAAACA TGTAGATCTGTCCGGCGAAGGCTTACGGACGCGGGTTCAACTCCCGCCAGCTCCACCA (SEQ ID NO:50)

TABLE 43 tmDNA Sequence for Ralstonia pickettii (Burkholderia) GGGGGCGGAAAGGATTCGACGGGGGTTGCGAAGCAGCGGAGGGCATACCGAGGACCCGTCACCT CGTTAATCAATGGGAATGCAATAACTGCTAACGACGAACGTTACGCACTGGCAGCCTAAGGGCC GCCGTCCTCGCACTGGCTCGCTGACGGGCTAGGGTCGCAAGACCAGCGAGGTCATTTACGTCAG ATAAGCTTTAGGTGAGTCACGGGCCTAGAGACGAAAACTTAGTGAATCGCCGTCGTAGAGCGTG TTCGTCCGCGATGCGGCGGTTAAATCAAATGACAGAACTAAGTATGTAGAACTCTCTGTGGAGG GCTTGCGGACGCGGGTTCGATTCCCGCCGCCTCACCACCA (SEQ ID NO:51)

TABLE 44 tmDNA Sequence for Variovax paradoxus (pseudomonas sp.) GGGGCTGATTCTGGATTCGACGTGGGTTCGGAGTCGCAGCGGGGCATGTCGAGCTGAATGCGCT CGTAAAACAGATTCAAACAAACTAACTGCAAACGACGAACGTTTCGCACTCGCTGCTTAATTGC CAGTGAGCCTTGCAACAGTTGGCCGATGGGCTGGGCAAGGGGGTCTGGAGCAATCCTGACCTCC CGGCTGCAAGGATAACTACATGGGCTGGCTCCGATCCGGGTACCTTGGGTCGGGGCGAGAAAAT AGGGTACTGGCGTCCGGTTTAGCGTGTGACTGCGCGACTCCGGAAGCGAGACTCAAAACAGATC ACTAAACATGTAGAACTGCGCGATGAAGGCTTGCGGACGGGGGTTCAACTCCCGCCAGCTCCACCA (SEQ ID NO:52)

TABLE 45 tmDNA Sequence for Bdellovibrio bacteriovorus (delta proteobacterie) GGGGGCGGAAAGGATTCGACGGGGGTGCTGAAGCATAAGGAGCATACCGGGGCGGATGAGGACC TCGTTAAAAACGTCCACTTTGTAATTGGCAACGATTACGCACTTGCAGCTTAATTAAGCAGCAC GATCAACCTTGTGGTGGTTCCGCACTTGGATTGATCGTCATTTAGGGACCTCGGCGTGTTGGGT TTTCTCCAGCAGACATGCTTAAATTTACTGGGGGAGAGGTCTTAGGGATTTTGTCTGTGGAAGC CCGAGGACCAATCTAAAACACTGACTAAGTATGTAGCGCCTTATCGTGGATCATTTGCGGACGG GGGTTCGATTCCCGCCGCCTCCACCA (SEQ ID NO:53)

TABLE 46 tmDNA Sequence for Myxococcus xanthus (delta proteobacterie) (SEQ ID NO:54) GGGGGCGGAAAGGATTCGACGGGGGCATTGAAGTTCGAGACGCGTGCCGAGCTTGTCAGGTAGC TCGTAAATTCAACCCGGCAAAGACACAAAAGCCAACGACAACGTTGAGCTCGCGCTGGCTGCCT AAAAACAGCCCATAGTGCGCGGTCCCCCCGCCCTCGGCCTGTGGGGTTGGGACAGACCGTCATA ATGCAGGCTGGCTGCCGAGGGTGCCTGGACCCGAGGTGGCGAGATCTTCCCAGGACCGGCTCTG AGTATCCCGTCCGTGGGAGCCTCAGGGACGTAGCAAATCGCGGACTACGCACGTAGGGTCGAAG AGCGGACGGCTTTCGGACGCGGGTTCGATTCCCGCCGCCTCCACCA

TABLE 47 tmDNA Sequence for Sulfurospirillum Deleyianum (SEQ ID NO:55) GGGGCTGATTCTGGATTCGACAGGAGTAGTTTTAGCTTATGGCTGCATGTCGGGAGTGAGGGTC TTCCGTTACACAACCTTCAAACAATAACTGCTAACAACAGTAACTATCGTCCTGCTTACGCGCT AGCTGCGTAAGTTTAACAAATAATGGACTGCTCTCCCCTTTGATGCTATCTTAGGAGGTCTTGG AGAGTATCATAGATTTGATAGCTATATTACATGAACGCCTTTACATGTAATGAAGTTAAAGGCT CGTTTTGCGTAGTTTTCTGATTGTTGTACGAAGCAAAATTAAACACTATCAACAATATCTAAGC ATGTAGACGTCATAGGTGGCTATTTTTGGACTGCGGGTTCAACTCCCGCCAGCTCCACCA

TABLE 48 tmDNA Sequence for Chromatium vinosum (SEQ ID NO:56) GGGGCTGATTCTGGATTCGACGTGGGTCGCGAAACCTAAGGTGCATGCCGAGGTGCGGTTGACC TCGTAAAACCCTCCGCAAACTTATAGTTGCCAACGACGACAACTACGCTCTCGCTGCTTAATCC CAGCGGGCCTCTGACCGTCACTTGCCTGTGGGCGGCGGATTCCAGGGGTAACCTCACACAGGAT CGTGGTGACGGGAGTCCGGACCTGATCCACTAAAACCTAACGGAATCGCCGACTGATCGCCCTG CCCTTCGGGCGGCAGAAGGCTAAAAACAATAGAGTGGGCTAAGCATGTAGGACCGAGGGCAGAG GGCTTGCGGACGCGGGTTCAACTCCCGCCAGCTCCACCA

TABLE 49 tmDNA Sequence for Pseudomonas fluorescens (gamma proteobacteria) (SEQ ID NO:57) GGGGCTGATTCTGGATTCGACGCCGGTTGCGAACCTTTAGGTGCATGCCGAGTTGGTAACAGAA CTCGTAAATCCACTGTTGCAACTTTCTATAGTTGCCAATGACGAAACCTACGGGGAATACGCTC TCGCTGCGTAAGCAGCCTTAGCCCTTCCCTCCTGGTACCTTCGGGTCCAGCAATCATCAGGGGA TGTCTGTAAACCCAAAGTGATTGTCATATAGAACAGAATCGCCGTGCAGTACGTTGTGGACGAA GCGGCTAAAACTTACACAACTCGCCCAAAGCACCCTGCCCGTCGGGTCGCTGAGGGTTAACTTA ATAGACACGGCTACGCATGTAGTACCGACAGCAGAGTACTGGCGGACGCGGGTTCAACTCCCGC CAGCTCCACCA

TABLE 50 tmDNA Sequence for Borrelia afzeli (SEQ ID NO:58) GGGGCTGATTCTGGATTCGACTGAAAATGCTAATATTGTAAGTTGCAAGCAGAGGGAATCTCTT AAAACTTCTAAAATAAATGCAAAAAATAATAACTTTACAAGTTCAAACCTTGTAATGGCTGCTT AAGTTAGCAGAGAGTTTTGTTGAATTTGGCTTTGAGATTCACTTATACTCTTTTAGACATCGAA GCTTGCTTAAAAATGTTTTCAAGTTGATTTTTAGGGACTTTTATACTTGAGAGCAATTTGGCGG TTTGCTAGTATTTCCAAACCATATTGCTTAGTAAAATACTAGATAAGCTTGTAGAAGCTTATAG TATTGTTTTTAGGACGCGGGTTCAACTCCCGCCAGTCCACCA

TABLE 51 tmDNA Sequence for Borrelia crociduarae (SEQ ID NO:59) GGGGCTGATTCTGGATTCGACTAAGAACTTTAGTAGCATAAATGGCAAGCAGAGTGAATCTCTT AAAACTTCTTTAATAAATGCAAAAAATAATAACTTTACAAGTTCAGATCTTGTAATGGCTGCTT AATTTAGCAGAGAGTTTTGTTGGATTTTGCTTTGAGGTTCAACTTATACTCTTTAAGACATCAA AGTATGCCTAAAAATGTTTCAAGTTGATTTTTAGGGACCTTTAAACTTGAGAGTAATTTGGTGG TTTGCTTGTTTTCCAAGCCTTATTGCTTTTTCTAAAAATTAGCTAAGCTTGTAGATATTTATGA TATTATTTTTAGGACGCGGGTTCAACTCCCGCCAGTTCCACCA

TABLE 52 tmDNA Sequence for Borrelia hermsii (SEQ ID NO:60) GGGGCTGATTCTGGATTCGACTAAAAACTTTAGTAGCATAAATTGCAAGCAGAGGGAATCTCTT AAAACTTCTTTAATAAATGCAAGAAATAATAACTTTACAAGTTCAAATCTTGTAATGGCTGCTT AAATTAGCAGAGAGTTCTGCTGGATTTTGCTTTGAGGTTCAGCTTATACTCTTTTAAGACATCA AAGCTTGCTTAAAAATATTTCAAGTTGATTTTTAGGGACTTTTAAATTTGAGAGTAATTTGGCG GTTTGCTAGTTTTTCCAAACCTTATTACTTAAAGAAAACACTAGCTAAGCTTGTAGATATTTAT GATATTATTTTTAGGACGCGGGTTCAACTCCCGCCAGCTCCACCA

TABLE 53 tmDNA Sequence for Borrelia garinii (SEQ ID NO:61) GGGGCTGATTCTGGATTCGACTGAAAATGCGAATATTGTAAGTTGCAGGCAGAGGGAATCTCTT AAAACTTCTAAAATAAATGCAAAAAATAATAACTTTACAAGCTCAAACCTTGTAATGGCTGCTT AAGTTAGCAGGGAGTTTCGTTGAATTTGGCTTTGAGGTTCACTTATACTCTTTTCGATATCGAA GCTTGCTTAAAAATGTTTTCAAGTTAATTTTTAGGGACTTTTGTACTTGAGAGCAATTTGGCGG TTTGCTAGTATTTCCAAACCATATTGCTTAAGTAAAATGCTAGATAAGCTTGTAGAAGCTTATA ATATTGTTTTTAGGACGCGGGTTCAACTCCCGCCAGTCCACCA

TABLE 54 tmDNA Sequence for Thermodesulfobacterium commune (70 degrees) (SEQ ID NO:62) GGGGGCGGAAAGGATTCGACGGGGATAGGTAGGATTAAACAGCAGGCCGTGGTCGCACCCAACC ACGTTAAATAGGGTGCAAAAACACAACTGCCAACGAATACGCCTACGCTTTGGCAGCCTAAGCG TGCTGCCACGCACCTTTAGACCTTGCCTGTGGGTCTAAAGGTGTGTGACCTAACAGGCTTTGGG AGGCTTAATCGGTGGGGTTAAGCCTCCCGAGATTACATCCCACCTGGTAGGGTTGCTTGGTGCC TGTGACAAGCACCCTACGAGATTTTCCCACAGGCTAAGCCTGTAGCGGTTTAATCTGAACTATC TCCGGACGCGGGTTCGATTCCCGCCGCCTCCCCACCA

TABLE 55 tmDNA Sequence for Thermotoga neapolitana (Thermotogales) (SEQ ID NO:63) GGGGGCGGAAAGGATTCGACGGGGATGGAGTCCCCTGGGAAGCGAGCCGAGGTCCCCACCTCCT CGTAAAAAAGGTGGGAACACGAATAAGTGCCAACGAACCTGTTGCTGTTGCCGCCTAATAGATA GGCGGCCGTCCTCTCCGGAGTTGGCTGGGCTCCGGAAGAGGGCGTGAGGGATCCAGCCTACCGA TCTGGGCTCCGCCTTCCGGCCCGGATCGGGAAGGTTCAGGAAGGCTGTGGGAAGCGACACCCTG CCCGTGGGGGGTCCTTCCCGAGACACGAAACACGGGCTGCGCTCGGAGAAGCCCAGGGGCCTCC ATCTTCNGACGCGGGTTCGATTCCCGCCACCTCCACCA

TABLE 56 tmDNA Sequence for Deinococcus proteolyticus (SEQ ID NO:64) GGGGGCGGAAAGGATTCGACGGGGGAACGGAAAGCGCTGCTGCGTGCCGAGGAGCCGTTGGCCT CGTAAACAAACGGCAAAGCCATTAACTGGCGAAAATAACTACGCTCTCGCTGCTTAAGTGAGAC AGTGACCACGTAGCCCCGCCTTTGGCGACGTGTGAACTGAGACAAAAGAAGGCTAGCTTAGGTG AGGTTCCATAGCCAAAAGTGAAACCAAATGGAAATAAGGCGGACGGCAGCCTGTTTGCTGGCAG CCCAGGCCCGACAATTTAAGAGCAGACTACGCACGTAGATGCACGCTGGATGGACCTTTGGACG CGGGTTCGATTCCCGCCAGCTCCACCA

TABLE 57 tmDNA Sequence for Prosthecobacter fusiformis (verrucomicrobia) (SEQ ID NO:65) GGGGCTGATTCTGGATTCGACGGGGAGTACAAGGATCAAAAGCTGCAAGCCGAGGTGCCGTTAC CTCGTAAAACAACGGCAAAAAAGAAGTGCCAACACAAATTTAGCATTAGCTGCTTAATTTAGCA GCTACGCTCTTCTAACCCGGGCTGGCAGGGTTAGAAGGGTGTCATAATGAGCCAGCTGCCCCTT CCGACTCCCCTAAGGAAGGGAAAGATGTAGGGGATAGGTGCTTACAGAATCCTGCGGGAGGGAG TCTGTAAGTGCCGAAAAGTTAAAACTCCCGCTAAGCTTGTAGAGGCTTTTGATTCTTGCTCTCT GGACGCGGGTTCAACTCCCGCCAGCTCCACCA

TABLE 58 tmDNA Sequence for Verrucomicrobium spinosum (verrucomicrobium) (SEQ ID NO:66) GGGNNNNATTTGGAATTCGCCGAATGCTAGAAGTGGAGGCTGCATGCCGCGGATGATTCGTTGG CCGCTTTACCAATTCGGATCAAACAACTAAATGCGGACTCTAACGAGCTTGCCCTCGCCGCTTA ATTGACGGTGACGTTCCTCCAGTGAAGTCTGTGAATTGGAGGAGCGACTACTTACAGGCTGGCC AAAAGAGCGGGCGACCGGCCCCAAGGCGAGATCTACAGGCCGCTGGATGGACGGCATCCTGGCA GTAGGAGGCTGGACATCGAGATCAAATNATTGCCTGAGCATGGAGACGCTTTCATAAAGGNGTT CGGACAGGG

Example 4 Alignment of tmRNA Sequences

The newly discovered tmRNA sequences and several known tmRNA sequences were aligned to identify target sites for drug development. The alignments of the sequences are shown in FIGS. 3A–11B. The nucleotides in the tmRNA sequences of these figures exist in several motifs (Felden et al., 1999). These motifs include nucleotides considered to be in RNA helices (Watson-Crick base-pairs GC or AU, or GU Wobble base-pairs). Nucleotides that are in in single stranded RNA domains, hence not base-paired. Some nucleotides in the single stranded domains are universally conserved nucleotides. Other nucleotides are the exceptions to a quasi-sequence conservation in the sequences alignment. Several nucleotides exist in well established non-canonical structural motifs in RNA structures; for example AG-GA pairs, AA pairs, etc. Some nucleotides are universally conserved Wobble GU base-pairs.

All the gene sequences have been decomposed in several structural domains that have been indicated with names at the top of each block of sequences. These domains are respectively from the 5′-end to the 3′-end of the sequences: H1, H5, H2, PK1, H4, PK2, PK3, PK4, H5 and H6. The bars delineate all the structural domains. H means helices and PK means pseudoknot. A pseudoknot is made of the pairing of parts of an RNA-loop with an upstream sequence. Consequently, two helices are made (shown in Felden et al., 1999) for all the 4 pseudoknots PK1 to PK4 for each sequence. Moreover, the tRNA-like domain as well as the coding sequence, namely the two functional units of the molecule, have also been indicated for each sequence.

The sequences, especially as identified by the sequence alignment, represent targets for the development of drugs which may be broadly applicable to many kinds of bacteria, or may be broadly applicable only to a particular genera of phylum of bacteria, or may be specifically applicable to a single species of bacteria.

Common Structural Features for Drug Targeting:

For all the novel tmRNA sequences, as well as with the ones that are already known, there are systematically several structural domains that are always found. These domains can be used as targets for the development of drugs which may be genera specific or which may be eubacteria specific. These domains are either RNA helices which can be sometimes interrupted by bulges or pseudoknots. The RNA helices which are always present are H1, H2, H5 and H6. Helices H1 and H6 are found in all canonical transfer RNAs. Thus, H1 and H6 are not good targets for drug development because drugs that would target them will also interfere with the biology of the individual that has a given disease. Consequently, very good candidates for development of drugs for targeting as many bacteria as possible are helices H2 and H5. Moreover, helices H2 and H5 are critical for the folding of all these tmRNA since both of them connect the two ends of the molecule together. Disruption of either H2 or H5 with a specific drug would lead to inactive tmRNA molecules in vivo. Similarly, pseudoknots PK1, PK2 and PK3 are always found in the bacterial tmRNAs. The PK1 structural domain is strictly conserved in the tmRNAs and is located upstream of the coding sequence. Since these pseudoknots are not found in all canonial transfer RNAs, they can also be targeted with specific drugs. Disruption of either PK1 or PK2 or PK3 with a specific drug would lead to inactive tmRNA molecules in vivo.

Specific Structural Features in Each Phylum that Could be Targeted by Drugs:

In addition to developing drugs which broadly target many bacteria, drugs are developed which are more genera specific. For trying to target specifically a given bacteria or a complete phylum, the coding sequence (shown in all the alignments) is a very good candidate. Indeed, this region of the RNA is very accessible for DNA antisense binding, which has been shown for Escherichia coli, and thus, is also available for interaction with other drugs. Moreover, this is a critical functional domain of the molecule in its quality-control mechanism in cells. In addition, this coding sequence would be the ideal target to use for designing specific PCR-based diagnostic assays for infection diseases.

Interestingly, some structural domains are present only in a given bacterial phyla and could be targeted for discovering a drug that will be specific of a phylum, but not of the others. For example:

-   -   (1) in the cyanobacteria, the fourth pseudoknot PK4 is made of         two smaller pseudoknots called PK4a and PK4b;     -   (2) in the mycoplasma, helix H2 is made of only 4 base-pairs         instead of 5 in the other species;     -   (3) for two sequences of chlorobium as well as Bacteroides         thetaiotaomicron and ppm gingiv., there is an additional domain         just downstream of the coding sequence that is unique to them;     -   (4) there is always a stem-loop in the coding sequence of the         actinobacteria (Felden et al., 1999); and     -   (5) all the beta proteobacteria possess a sequence insertion in         pseudoknot PK2 (shown in the alignment).

The novel sequences described herein, when aligned, show that specific structural domains within tmRNA are strictly conserved, as for example pseudoknot PK1 is located upstream (at the 5′-side) of the coding sequence. As previously disclosed, this pseudoknot is a target for future anti-bacterial drugs. Moreover, recent data have shown that this PK1 pseudoknot, among all the four pseudoknots within tmRNA gene sequences (sometimes there's only 2 or 3 detectable pseudoknots, depending upon the sequences), is the only one that its correct folding is essential for the biological activity of tmRNA (Nameki et al., 1999; Nameki et al., 2000).

While the invention has been disclosed in this patent application by reference to the details of preferred embodiments of the invention, it is to be understood that the disclosure is intended in an illustrative rather than in a limiting sense, as it is contemplated that modifications will readily occur to those skilled in the art, within the spirit of the invention and the scope of the appended claims.

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1. An isolated nucleic acid sequence selected from the group consisting of the tmDNA sequence for Staphylococcus epidermidis set forth in SEQ ID NO: 31, the complement of said tmDNA sequence, and the tmRNA sequence set forth in SEQ ID NO:
 85. 2. A method for diagnosing the presence of Staphylococcus epidermidis comprising determining the presence of a bacterial nucleic acid sequence selected from the group consisting of the tmDNA sequence for Staphylococcus epidermidis set forth in SEQ ID NO: 31, the complement of said tmDNA sequence, and the tmRNA sequence set forth in SEQ ID NO:
 85. 3. The method of claim 2 wherein the determination is made by performing an amplification-based assay.
 4. The isolated nucleic acid sequence of claim 1, wherein the nucleic acid sequence is the tmDNA sequence for Staphylococcus epidermidis set forth in SEQ ID NO:
 31. 5. The method of claim 2, wherein the bacterial nucleic acid sequence is the tmDNA sequence for Staphylococcus epidermidis set forth in SEQ ID NO:
 31. 6. The method of claim 3, wherein the bacterial nucleic acid sequence is the tmDNA sequence for Staphylococcus epidermidis set forth in SEQ ID NO:
 31. 